Brian K. Talbot
Examiner (ID: 12143, Phone: (571)272-1428 , Office: P/1715 )
| Most Active Art Unit | 1715 |
| Art Unit(s) | 1112, 1762, 1715, 1792 |
| Total Applications | 2278 |
| Issued Applications | 1359 |
| Pending Applications | 219 |
| Abandoned Applications | 736 |
Applications
| Application number | Title of the application | Filing Date | Status |
|---|---|---|---|
Array
(
[id] => 14749225
[patent_doc_number] => 20190257786
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-08-22
[patent_title] => METHODS FOR FABRICATING PRINTED FLEXIBLE SENSORS
[patent_app_type] => utility
[patent_app_number] => 16/400322
[patent_app_country] => US
[patent_app_date] => 2019-05-01
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 4957
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -5
[patent_words_short_claim] => 111
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16400322
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/400322 | Printed flexible sensors | Apr 30, 2019 | Issued |
Array
(
[id] => 16477670
[patent_doc_number] => 10852614
[patent_country] => US
[patent_kind] => B2
[patent_issue_date] => 2020-12-01
[patent_title] => Method of forming electrical contacts in layered structures
[patent_app_type] => utility
[patent_app_number] => 16/398666
[patent_app_country] => US
[patent_app_date] => 2019-04-30
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 9
[patent_figures_cnt] => 24
[patent_no_of_words] => 17144
[patent_no_of_claims] => 16
[patent_no_of_ind_claims] => 2
[patent_words_short_claim] => 114
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => patent
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16398666
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/398666 | Method of forming electrical contacts in layered structures | Apr 29, 2019 | Issued |
Array
(
[id] => 16402576
[patent_doc_number] => 20200343434
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2020-10-29
[patent_title] => THROUGH-SILICON-VIA FABRICATION IN PLANAR QUANTUM DEVICES
[patent_app_type] => utility
[patent_app_number] => 16/396992
[patent_app_country] => US
[patent_app_date] => 2019-04-29
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 7812
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -22
[patent_words_short_claim] => 81
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16396992
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/396992 | Through-silicon-via fabrication in planar quantum devices | Apr 28, 2019 | Issued |
Array
(
[id] => 17734871
[patent_doc_number] => 20220220330
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2022-07-14
[patent_title] => METHOD FOR MANUFACTURING ELECTRICALLY CONDUCTIVE MEMBER
[patent_app_type] => utility
[patent_app_number] => 17/605923
[patent_app_country] => US
[patent_app_date] => 2019-04-26
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 15452
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -18
[patent_words_short_claim] => 2
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17605923
[rel_patent_id] =>[rel_patent_doc_number] =>) 17/605923 | Method for manufacturing electrically conductive member | Apr 25, 2019 | Issued |
Array
(
[id] => 14994031
[patent_doc_number] => 20190315973
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-10-17
[patent_title] => Flexible Superhydrophobic and/or Oleophobic Polyurethane Coatings
[patent_app_type] => utility
[patent_app_number] => 16/390212
[patent_app_country] => US
[patent_app_date] => 2019-04-22
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 22491
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -17
[patent_words_short_claim] => 2
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16390212
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/390212 | Flexible Superhydrophobic and/or Oleophobic Polyurethane Coatings | Apr 21, 2019 | Abandoned |
Array
(
[id] => 14961915
[patent_doc_number] => 20190308435
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-10-10
[patent_title] => PAPER, LABELS MADE THEREFROM AND METHODS OF MAKING PAPER AND LABELS
[patent_app_type] => utility
[patent_app_number] => 16/388489
[patent_app_country] => US
[patent_app_date] => 2019-04-18
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 13594
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -12
[patent_words_short_claim] => 2
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16388489
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/388489 | Methods of making paper and labels | Apr 17, 2019 | Issued |
Array
(
[id] => 17367285
[patent_doc_number] => 11234334
[patent_country] => US
[patent_kind] => B2
[patent_issue_date] => 2022-01-25
[patent_title] => Guided transport path correction
[patent_app_type] => utility
[patent_app_number] => 16/385435
[patent_app_country] => US
[patent_app_date] => 2019-04-16
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 14
[patent_figures_cnt] => 29
[patent_no_of_words] => 29384
[patent_no_of_claims] => 14
[patent_no_of_ind_claims] => 1
[patent_words_short_claim] => 169
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => patent
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16385435
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/385435 | Guided transport path correction | Apr 15, 2019 | Issued |
Array
(
[id] => 15030219
[patent_doc_number] => 20190326114
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-10-24
[patent_title] => METHODS OF TREATING A SUBSTRATE TO FORM A LAYER THEREON FOR APPLICATION IN SELECTIVE DEPOSITION PROCESSES
[patent_app_type] => utility
[patent_app_number] => 16/381755
[patent_app_country] => US
[patent_app_date] => 2019-04-11
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 11232
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -17
[patent_words_short_claim] => 50
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16381755
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/381755 | METHODS OF TREATING A SUBSTRATE TO FORM A LAYER THEREON FOR APPLICATION IN SELECTIVE DEPOSITION PROCESSES | Apr 10, 2019 | Abandoned |
Array
(
[id] => 17236972
[patent_doc_number] => 11180844
[patent_country] => US
[patent_kind] => B2
[patent_issue_date] => 2021-11-23
[patent_title] => Process for making alkali metal vapor cells
[patent_app_type] => utility
[patent_app_number] => 16/357650
[patent_app_country] => US
[patent_app_date] => 2019-03-19
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 15
[patent_figures_cnt] => 15
[patent_no_of_words] => 7715
[patent_no_of_claims] => 19
[patent_no_of_ind_claims] => 2
[patent_words_short_claim] => 296
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => patent
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16357650
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/357650 | Process for making alkali metal vapor cells | Mar 18, 2019 | Issued |
Array
(
[id] => 17310468
[patent_doc_number] => 11211595
[patent_country] => US
[patent_kind] => B2
[patent_issue_date] => 2021-12-28
[patent_title] => Method for manufacturing negative electrode
[patent_app_type] => utility
[patent_app_number] => 16/966269
[patent_app_country] => US
[patent_app_date] => 2019-03-06
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 1
[patent_figures_cnt] => 1
[patent_no_of_words] => 6129
[patent_no_of_claims] => 5
[patent_no_of_ind_claims] => 1
[patent_words_short_claim] => 185
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => patent
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16966269
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/966269 | Method for manufacturing negative electrode | Mar 5, 2019 | Issued |
Array
(
[id] => 14785465
[patent_doc_number] => 20190267630
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-08-29
[patent_title] => ANODE FOR LITHIUM METAL SECONDARY BATTERY INCLUDING MXENE THIN FILM, METHOD FOR PRODUCING THE ANODE AND LITHIUM METAL SECONDARY BATTERY INCLUDING THE ANODE
[patent_app_type] => utility
[patent_app_number] => 16/285680
[patent_app_country] => US
[patent_app_date] => 2019-02-26
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 7686
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -5
[patent_words_short_claim] => 41
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16285680
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/285680 | Method for producing an anode for a lithium metal secondary battery including a MXene thin film | Feb 25, 2019 | Issued |
Array
(
[id] => 17883211
[patent_doc_number] => 20220298688
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2022-09-22
[patent_title] => DEDUST COMPOSITIONS FOR TREATMENT OF MINERAL FIBERS
[patent_app_type] => utility
[patent_app_number] => 17/432047
[patent_app_country] => US
[patent_app_date] => 2019-02-21
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 5769
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -19
[patent_words_short_claim] => 2
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 17432047
[rel_patent_id] =>[rel_patent_doc_number] =>) 17/432047 | DEDUST COMPOSITIONS FOR TREATMENT OF MINERAL FIBERS | Feb 20, 2019 | Pending |
Array
(
[id] => 16516336
[patent_doc_number] => 20200395594
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2020-12-17
[patent_title] => PREDOPING METHOD FOR NEGATIVE ELECTRODE ACTIVE MATERIAL, MANUFACTURING METHOD FOR NEGATIVE ELECTRODE, AND MANUFACTURING METHOD FOR POWER STORAGE DEVICE
[patent_app_type] => utility
[patent_app_number] => 16/971968
[patent_app_country] => US
[patent_app_date] => 2019-02-21
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 13326
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -5
[patent_words_short_claim] => 103
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16971968
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/971968 | Predoping method for negative electrode active material, manufacturing method for negative electrode, and manufacturing method for power storage device | Feb 20, 2019 | Issued |
Array
(
[id] => 16368171
[patent_doc_number] => 10799908
[patent_country] => US
[patent_kind] => B2
[patent_issue_date] => 2020-10-13
[patent_title] => Electrically conductive pattern printer for downhole tools
[patent_app_type] => utility
[patent_app_number] => 16/263878
[patent_app_country] => US
[patent_app_date] => 2019-01-31
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 4
[patent_figures_cnt] => 7
[patent_no_of_words] => 3300
[patent_no_of_claims] => 16
[patent_no_of_ind_claims] => 2
[patent_words_short_claim] => 47
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => patent
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16263878
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/263878 | Electrically conductive pattern printer for downhole tools | Jan 30, 2019 | Issued |
Array
(
[id] => 17844014
[patent_doc_number] => 11433359
[patent_country] => US
[patent_kind] => B1
[patent_issue_date] => 2022-09-06
[patent_title] => Antimicrobial filtration membranes
[patent_app_type] => utility
[patent_app_number] => 16/261496
[patent_app_country] => US
[patent_app_date] => 2019-01-29
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 12
[patent_figures_cnt] => 29
[patent_no_of_words] => 7591
[patent_no_of_claims] => 26
[patent_no_of_ind_claims] => 1
[patent_words_short_claim] => 60
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => patent
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16261496
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/261496 | Antimicrobial filtration membranes | Jan 28, 2019 | Issued |
Array
(
[id] => 15300685
[patent_doc_number] => 20190393478
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-12-26
[patent_title] => Methods, Systems, and Compositions for the Liquid-Phase Deposition of Thin Films onto the Surface of Battery Electrodes
[patent_app_type] => utility
[patent_app_number] => 16/244024
[patent_app_country] => US
[patent_app_date] => 2019-01-09
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 12559
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -28
[patent_words_short_claim] => 2
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16244024
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/244024 | Methods, systems, and compositions for the liquid-phase deposition of thin films onto the surface of battery electrodes | Jan 8, 2019 | Issued |
Array
(
[id] => 15300685
[patent_doc_number] => 20190393478
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-12-26
[patent_title] => Methods, Systems, and Compositions for the Liquid-Phase Deposition of Thin Films onto the Surface of Battery Electrodes
[patent_app_type] => utility
[patent_app_number] => 16/244024
[patent_app_country] => US
[patent_app_date] => 2019-01-09
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 12559
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -28
[patent_words_short_claim] => 2
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16244024
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/244024 | Methods, systems, and compositions for the liquid-phase deposition of thin films onto the surface of battery electrodes | Jan 8, 2019 | Issued |
Array
(
[id] => 15263803
[patent_doc_number] => 20190380635
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2019-12-19
[patent_title] => Dual-Sided Biomorphic Polymer-based Microelectrode Array and Fabrication Thereof
[patent_app_type] => utility
[patent_app_number] => 16/234570
[patent_app_country] => US
[patent_app_date] => 2018-12-28
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 2967
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => 0
[patent_words_short_claim] => 15
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16234570
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/234570 | Dual-Sided Biomorphic Polymer-based Microelectrode Array and Fabrication Thereof | Dec 27, 2018 | Abandoned |
Array
(
[id] => 16207925
[patent_doc_number] => 20200240915
[patent_country] => US
[patent_kind] => A1
[patent_issue_date] => 2020-07-30
[patent_title] => Apparatus and Method for Monitoring Dry State of Electrode Substrate
[patent_app_type] => utility
[patent_app_number] => 16/652290
[patent_app_country] => US
[patent_app_date] => 2018-12-17
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 0
[patent_figures_cnt] => 0
[patent_no_of_words] => 3763
[patent_no_of_claims] => 0
[patent_no_of_ind_claims] => -9
[patent_words_short_claim] => 62
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => publication
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16652290
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/652290 | Method for monitoring dry state of electrode substrate | Dec 16, 2018 | Issued |
Array
(
[id] => 16928567
[patent_doc_number] => 11050062
[patent_country] => US
[patent_kind] => B2
[patent_issue_date] => 2021-06-29
[patent_title] => Methods of fabricating solid oxide fuel cells
[patent_app_type] => utility
[patent_app_number] => 16/211494
[patent_app_country] => US
[patent_app_date] => 2018-12-06
[patent_effective_date] => 0000-00-00
[patent_drawing_sheets_cnt] => 8
[patent_figures_cnt] => 9
[patent_no_of_words] => 7630
[patent_no_of_claims] => 20
[patent_no_of_ind_claims] => 1
[patent_words_short_claim] => 155
[patent_maintenance] => 1
[patent_no_of_assignments] => 0
[patent_current_assignee] =>[type] => patent
[pdf_file] =>[firstpage_image] =>[orig_patent_app_number] => 16211494
[rel_patent_id] =>[rel_patent_doc_number] =>) 16/211494 | Methods of fabricating solid oxide fuel cells | Dec 5, 2018 | Issued |